Electrospinning can fabricate nanofibers, the most popular material in building scaffold for the field of regenerative medicine and tissue engineering. Yet, scaffolds retrieved from electrospinning are too thin, and the pore size are uncontrollable. In order to solve these problem, this study tried to conduct the experiments based on the concept of salt-leaching, and using gelatin/ 2,2,2trifluroethanol and poly-carpolactone/ trifluoroacetic acid as primary materials to create gelatin nanofiber and PCL microparticle respectively. Many parameters will affect the results of electrospinning. Therefore,in order to find out the most important factor in controlling the experimented results, we used orthogonal design method to investigate the interation of different parameters such as concentration, voltage, flowing speed and needle size. First, we controlled the concentration within 2.5 % to 12.5 %; voltage 9 kV to 21 kV at 3 kV increment intervals; flow rate 0.9 ml/h to 9 ml/h. SPSS software was used to analyze the relationship between different parameters and diameters. We found that the concentration is the most important factor, followed by voltage, needle size, and flowing speed. Nanofiber ranging from 50 nm~800 nm and PCL microparticle 10 μm~100 μm for further usage were created when the factors were under control. 7.5 % w/v gelatin/TFE solution and 7.5 % w/v PCL/TFA solution were used as raw materials and electrospun at the same time. A rotation device was especially designed to have the composite well mixed. The electrospun gelatin nanofibers were crosslinked with 25 % saturated glutaraldehyde (GTA) vapor at room temperature in a Petri dish under different time duration. Then acetone was used to dissolve PCL particle to obtain desirable pore sizes. Experimental results show that the study successfully designed and achieved a scaffold of nanofibers with desirable pore sizes using electrospinning technique. As an appendix, a device similar to sugar puff machine was built to cope with the problem of thickness. 3-D cotton fibers were collected from both wire meshes and trigonometric wire. Scaffolds with thickness were obtained and the fibers collected were uniaxially aligned.